| Molecular crowding of collagen: a pathway to produce highly-organized collagenous structures N Saeidi, KP Karmelek, JA Paten, R Zareian, E DiMasi, JW Ruberti Biomaterials 33 (30), 7366-7374, 2012 | 109 | 2012 |
| Production-scale fibronectin nanofibers promote wound closure and tissue repair in a dermal mouse model CO Chantre, PH Campbell, HM Golecki, AT Buganza, AK Capulli, ... Biomaterials 166, 96-108, 2018 | 93 | 2018 |
| Flow-Induced Crystallization of Collagen: A Potentially Critical Mechanism in Early Tissue Formation JA Paten, SM Siadat, ME Susilo, EN Ismail, JL Stoner, JP Rothstein, ... ACS nano, 2016 | 81 | 2016 |
| Collagen network strengthening following cyclic tensile loading ME Susilo, JA Paten, EA Sander, TD Nguyen, JW Ruberti Interface focus 6 (1), 20150088, 2016 | 53 | 2016 |
| Molecular interactions between collagen and fibronectin: a reciprocal relationship that regulates de novo fibrillogenesis JA Paten, CL Martin, JT Wanis, SM Siadat, AM Figueroa-Navedo, ... Chem 5 (8), 2126-2145, 2019 | 48 | 2019 |
| Differential contributions of conformation extension and domain unfolding to properties of fibronectin nanotextiles LF Deravi, T Su, JA Paten, JW Ruberti, K Bertoldi, KK Parker Nano letters 12 (11), 5587-5592, 2012 | 35 | 2012 |
| Utility of an optically-based, micromechanical system for printing collagen fibers JA Paten, GE Tilburey, EA Molloy, R Zareian, CV Trainor, JW Ruberti Biomaterials 34 (11), 2577-2587, 2013 | 34 | 2013 |
| Human corneal fibroblast pattern evolution and matrix synthesis on mechanically-biased substrates R Zareian, ME Susilo, JA Paten, JP McLean, J Hollmann, D Karamichos, ... Tissue Engineering, 2016 | 19 | 2016 |
| Design and performance of an optically accessible, low-volume, mechanobioreactor for long-term study of living constructs JA Paten, R Zareian, N Saeidi, SA Melotti, JW Ruberti Tissue Engineering Part C: Methods 17 (7), 775-788, 2011 | 16 | 2011 |
| Protein‐based hydrogels that actuate self‐folding systems CM Gomes, C Liu, JA Paten, SM Felton, LF Deravi Advanced Functional Materials 29 (4), 1805777, 2019 | 15 | 2019 |
| A role for monosaccharides in nucleation inhibition and transport of collagen CL Martin, MR Bergman, LF Deravi, JA Paten Bioelectricity 2 (2), 186-197, 2020 | 11 | 2020 |
| Development of Fluorescently Labeled, Functional Type I Collagen Molecules SM Siadat, AA Silverman, ME Susilo, JA Paten, CA DiMarzio, JW Ruberti Macromolecular Bioscience 22 (3), 2100144, 2022 | 4 | 2022 |
| Design and Production of Customizable and Highly Aligned Fibrillar Collagen Scaffolds CL Martin, C Zhai, JA Paten, J Yeo, LF Deravi ACS Biomaterials Science & Engineering 9 (7), 3962-3971, 2021 | 4 | 2021 |
| Development and validation of fluorescently labeled, functional type I collagen molecules SM Siadat, ME Susilo, JA Paten, AA Silverman, CA DiMarzio, JW Ruberti bioRxiv, 2021.03. 26.437209, 2021 | 2 | 2021 |
| Collagenous Tissue Repair Device JA Paten, JW Ruberti US Patent App. 15/536,358, 2017 | 1* | 2017 |
| Design and Production of Customizable and Highly Aligned Fibrillar Collagen Scaffolds CL Martin, L Deravi, J Paten US Patent App. 18/264,536, 2024 | | 2024 |
| Collagen Nucleation Inhibitors J Paten US Patent App. 17/915,638, 2023 | | 2023 |
| Mechanochemical collagen assembly JW Ruberti, J Paten US Patent 10,888,637, 2021 | | 2021 |
| Mechanochemical Collagen Assembly JW Ruberti, J Paten US Patent 10,213,523, 2019 | | 2019 |
| Investigation into the Mechano-Chemistry of De Novo Collagen Assembly JA Paten Northeastern University, 2014 | | 2014 |
